A method of manufacturing an electronic device, such as a high-speed semiconductor integrated circuit device, with improved dimensional accuracy in transferring fine patterns.
Photolithography for gate patterns and wiring patterns is carried out by exposing a halftone phase-shift mask having shade areas made of resist with an oblique illumination system, and photolithography for contact hole patterns is carried out by using a photomask having a metal shade film with metal alignment wafer marks.
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1. A method of manufacturing an electronic device, comprising:
providing a halftone phase-shift mask having a halftone phase-shift pattern formation area including a circuit pattern with plurality of discrete circuit pattern components arranged on an optically transmissive plate, and a resist shade film disposed outside the pattern formation area and having portions arranged to embrace at least part of the pattern formation area; and obliquely illuminating the mask, thereby transferring the circuit patter to a photosensitive film provided on a surface of a workpiece.
13. A method of manufacturing an electronic circuit device, comprising:
performing lithography using (i) a first photomask with a resist shade film filtering out exposure light, the resist shade film being located outside a pattern formation area in which a circuit pattern having a plurality of discrete circuit pattern components is disposed and having portions arranged to embrace at least part of the pattern formation area, and (ii) a second photomask with a metal shade film filtering out exposure light and provided outside a pattern formation area of the second photomask.
14. A method of manufacturing an electronic circuit device, comprising:
performing lithography using a plurality of halftone phase-shift masks each having an exposure light transmitting area and an area in which the exposure light is dimmed and reversed in phase, wherein one of said masks is a halftone phase-shift mask with a resist shade film which filters out exposure light, the resist shade film being located outside a pattern formation area including a plurality of discrete circuit pattern components, and the resist shade film having portions arranged to embrace at least part of the pattern formation area, and wherein another of said masks is a photomask with a metal film which filters out exposure light outside a pattern formation area of said another mask.
11. A method of manufacturing an electronic device, comprising:
mounting a halftone phase-shift mask on a reduction projection aligner, the halftone phase-shift mask being formed on an optically transmissive plate and including a pattern formation area with a halftone phase-shift film in which a circuit pattern having a plurality of discrete circuit pattern components and mask alignment marks are formed, and a resist shade film provided outside the pattern formation area and having portions arranged to embrace at least part of the pattern formation area; aligning the halftone phase-shift mask and a wafer with reference to the mask alignment marks formed in the halftone film; and exposing a photosensitive film provided on a main surface of the wafer to light obliquely incident through the halftone phase-shift mask.
10. A method of manufacturing an electronic device, comprising:
providing a photomask having a circuit pattern including a plurality of discrete circuit pattern components formed in a circuit pattern formation area on an optically transmissive plate, and a resist shade film provided in an area outside the pattern formation area and having portions arranged to embrace at least part of the circuit pattern formation area to filter out exposure light; and transferring the circuit pattern a plurality of times to different transfer locations on a photosensitive film provided on a main surface of a workpiece, by exposing the workpiece to obliquely incident light through the photomask in a stepped or scanned manner, such that transfer areas on the workpiece corresponding to the resist film partially overlap for different exposures.
12. A method of manufacturing an electronic device, comprising:
providing a half tone phase-shift mask having a halftone phase-shift pattern including a plurality of discrete circuit pattern components provided in a pattern formation area on an optically transmissive plate, and a resist shade film provided outside the pattern formation area and having portions arranged to embrace at least part of the pattern formation area; mounting the half tone phase-shift mask on a projection aligner with the resist shade film being kept from touching a mask transportation and support system; and exposing the pattern a plurality of times, with light obliquely incident through the mask, onto different adjacent areas of a photosensitive film provided on a surface of a workpiece in such a way that transfer areas on the photosensitive film corresponding to the resist film are partially overlapping for different exposures.
9. A method of manufacturing an electronic device, comprising the steps of:
preparing a halftone phase-shift mask having a circuit pattern formation area formed on an optically transmissive plate with a halftone film pattern for dimming exposure light and shifting the phase of the exposure light, the circuit pattern formation area including a plurality of discrete circuit pattern components, and a resist shade film provided outside the circuit pattern formation area having portions arranged to embrace at least part of the circuit pattern formation area; irradiating the circuit pattern formation area of the halftone phase-shift mask with light, and inspecting for presence or absence of resist residue on the mask by observing fluorescence; and using the inspected halftone phase-shift mask to expose a photosensitive film provided on a main surface of a workpiece and thereby transfer the circuit pattern to the photosensitive film.
4. A method of manufacturing an electronic device, wherein a plurality of masks are used to form a hole pattern and a wiring pattern on a workpiece, said method comprising:
conducting a first projection exposure process using a binary mask comprising a shade part and an optically transmissive part provided on a first optically transmissive plate and having a plurality of discrete pattern components corresponding to the hole pattern, thereby transferring the hole pattern to the workpiece; and conducting a second projection exposure process using a halftone phase-shift mask having a halftone phase-shift pattern formation area, including a plurality of discrete pattern components corresponding to the wiring pattern, and a resist shade film provided outside the pattern formation area with portions arranged to embrace at least part of the pattern formation area on a second optically transmissive plate, thereby transferring the wiring pattern to the workpiece.
3. A method of manufacturing an electronic device, wherein a plurality of masks are used to form a hole pattern and a wiring pattern on a workpiece, said method comprising:
conducting a first projection exposure process using a first halftone phase-shift mask having a first halftone phase-shift pattern formation area including a plurality of discrete pattern components corresponding to the hole pattern provided on a first optically transmissive plate, and a metal shade film provided on the surface of the first optically transmissive plate outside the first pattern formation area, thereby transferring the hole pattern to the workpiece; and conducting a second projection exposure process using a second halftone phase-shift mask having a second halftone phase-shift pattern formation area including a plurality of discrete pattern components corresponding to the wiring pattern provided on second optically transmissive plate, and a band-like resist shade film provided outside the second pattern formation area and having portions arranged to embrace at least art of the second pattern formation area, thereby transferring the wiring pattern to the workpiece.
7. A method of manufacturing a semiconductor integrated circuit device, comprising:
forming a fine hole pattern in each of a plurality of regions of a dielectric film provided on a semiconductor substrate having a corresponding plurality of semiconductor regions; said fine hole pattern forming step being conducted using a binary mask to expose a first photosensitive film provided on the dielectric film, the binary mask comprising a shade part and an optically transmissive part provided on a first optically transmissive plate and having a plurality of discrete pattern components corresponding to the hole pattern; and forming a wiring pattern in each of a plurality of regions of a conductive layer provided on the semiconductor substrate in correspondence with said plurality of semiconductor regions; said wiring pattern forming step being conducted using a halftone phase-shift mask to expose a second photosensitive film provided on the conductive layer, the second halftone phase-shift mask having a halftone phase-shift pattern formation area including a plurality of discrete pattern components corresponding to the wiring pattern provided on a second optically transmissive plate, and a resist shade film provided outside the pattern formation area on the second optically transmissive plate and having portions arranged to embrace at least part of the pattern formation area.
5. A method of manufacturing a semiconductor integrated circuit device, comprising:
forming a fine hole pattern in each of a plurality of regions of a dielectric film provided on a semiconductor substrate having a corresponding plurality of semiconductor regions; said fine hole pattern forming step being conducted using a first halftone phase-shift mask to expose a first photosensitive film provided on the dielectric film, the first halftone phase-shift mask having a first halftone phase-shift pattern formation area including a plurality of discrete pattern components corresponding to the fine hole pattern arranged on surface of a first optically transmissive plate, and a metal shade film provided outside the first pattern formation area on the surface of the first optically transmissive plate; and forming a wiring pattern in each of a plurality of regions of a conductive layer provided on the semiconductor substrate in correspondence with said plurality of semiconductor regions; said wiring pattern forming step being conducted using a second halftone phase-shift mask to expose a second photosensitive film provided on the conductive layer, the second halftone phase-shift mask having a second halftone phase-shift pattern formation area including a plurality of discrete pattern components corresponding to the wiring pattern provided on a surface of a second optically transmissive plate, and a resist shade film provided outside the second pattern formation area on the surface of the second optically transmissive plate and having portions arranged to embrace at least part of the second pattern formation area.
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1.Field of the Invention
The present invention relates to a method of manufacturing an electronic device having fine patterns, more particularly to a method of manufacturing a semiconductor integrated circuit device having a plurality of fine circuit patterns.
2. Prior Art
In the manufacture of semiconductor integrated circuit devices, repetitive use is made of an epitaxial process such as a chemical vapor deposition (CVD) process, a doping process such as ion implantation, a lithographic process, and an etching process. The operation speed and integration density of semiconductor integrated circuit devices can be effectively improved by miniaturizing the circuit patterns and enhancing the dimensional accuracy, as has increasingly been done in recent years. The miniaturization of circuit patterns mainly depends on lithography, so lithography plays a vital role in the manufacture of semiconductor integrated circuit devices.
Lithographic technology mainly employs a projection aligner that forms device patterns by transferring the pattern of a photomask mounted in the projection aligner to the surface of a semiconductor wafer. At this time, the exposure area of a high-resolution projection aligner is smaller than the area of a semiconductor wafer, so the exposure is divided into a plurality of shots which are stepped or scanned to repeat the exposure of the chip area a plurality of times. The size of a chip depends on the product to be made, so a photomask is, in general, provided with an outer frame referred to as a shade area made of a metal such as chromium (Cr) so that a desired shot size can be obtained. In this way, the single chip areas exposed by the plurality of shots are prevented from overlapping, and a scribe area is provided around the edge of each chip for dicing.
The need for higher integration and faster device operation has led to the increasing miniaturization of the patterns formed by lithography in recent years. In this context, research and development aimed at shortening the wavelength of exposure light used for exposing patterns in an optical aligner are being pursued.
Furthermore, a halftone phase-shifting exposure method is now being used. A halftone phase-shift mask is a translucent film (referred to as a halftone film) formed on a transparent plate to dim the exposure light and shift its phase. In general, a transmittance in the range of 1% to 25% of the exposure light is considered desirable.
Exposure light which passes through a halftone film is phase shifted with respect to exposure light which does not pass thorough the film. Either a single layer or a multi-layer halftone film can be used to produce the phase difference. Although phase differences of 180°C and odd multiples thereof are needed to obtain the highest resolution, other phase differences within a range of 180°C±90°C are also effective in improving resolution. It is known that use of a halftone mask can improve the resolution by about 5% to 20%.
Descriptions of halftone phase-shifting can be found, for example, in documents such as JP-A No. H5-181257.
As described above, a halftone phase-shifting method is known as an exposure method that can resolve fine-dimensioned patterns with high resolution. This exposure method, however, has many problems as described below, making it difficult to obtain sufficient pattern transferring accuracy.
The halftone phase-shifting method causes interference between exposure light which has passed through the halftone part and exposure light which has passed through apertures therein, in the vicinity of the boundaries of the apertures and the halftone part, to enhance the optical contrast, thereby improving the resolution and exposure tolerances. For this reason, it is very critical to control the amount of exposure light passing through the halftone part, or the transmittance of the halftone part, and the amount of the phase shift.
In addition, the dimensional accuracy of the halftone film pattern has a profound effect on the dimensional accuracy of the transferred pattern. For a fine pattern near the resolution limit of the projection lens, the optical contrast becomes substantially lower due to light diffraction which, together with a factor referred to as the mask error enhancement factor (MEF), makes the dimensional accuracy of the transferred pattern lower than that of the pattern on the mask. The MEF is an indicator showing the amplification of the dimensional difference ΔLm of a transferred pattern in relation to the dimensional difference ΔLw of the pattern on a mask, and is given by the equation MEF=ΔLm/ (M·ΔLw), where M is the reduction factor of the projection lens. If a 5× lens is used, then M is ⅕. In a case with a fine pattern using a halftone phase-shift mask, the pattern is generally transferred with an MEF of 2 to 3, so that unwanted variations in the dimensions of the pattern on the mask are amplified by a factor of 2M to 3M.
In the manufacturing processes of a semiconductor integrated circuit device, a step that requires particularly high dimensional accuracy in a fine pattern is the patterning step for the gate electrodes of transistors. As the dimensions of the gate electrodes become smaller, the operation speed of the transistors becomes higher. High dimensional accuracy of the gate electrodes enables stable operation of the circuit and thus enables high-speed circuits to work together, consequently increasing the added value of a semiconductor integrated circuit device. In addition, if fine patterns can be formed with higher accuracy in the wiring patterning process, interconnection wirings can result in a higher packing density and shorter length, which also contribute to high-speed circuit operation and a higher integration density.
However, if the conventional halftone phase-shift exposure method is adopted for extremely fine gate, wiring, and hole patterning processes, there is a problem in that sufficient dimensional accuracy cannot be obtained due to the inadequate controllability of the phase and transmittance of the halftone phase-shift mask and variations of dimensions on the mask, and consequently the reproducibility and yield of the manufacturing process cannot be improved.
It is an object of this invention to provide an improved method of manufacturing an electronic device having fine dimensional patterns.
It is another object of this invention to provide an improved method of manufacturing a semiconductor circuit device having fine circuit patterns, so that higher integration levels and higher-speed operation can be obtained.
It is a further specific object of this invention to provide an improved method of manufacturing a high-speed, highly integrated semiconductor integrated circuit device by forming fine patterns for gate electrodes, wirings, and holes with better dimensional accuracy.
Typical aspects of the invention disclosed herein will be described below. Although the following description focuses on a method of manufacturing a semiconductor integrated circuit device, the invention is also applicable to methods of manufacturing other electronic devices having extremely fine patterns, such as liquid crystal display devices, micro machines, and superconductive devices. In accordance with a first aspect of the invention, a mask having shade areas made of resist external to the halftone phase-shift pattern is used to expose a photosensitive film provided on the surface of a workpiece such as a semiconductor wafer with an oblique illumination system to transfer a fine pattern.
The mask or other workpiece is exposed by stepping or scanning the exposure shots, thus repeating the exposure a plurality of times, in such a way that the resist shade areas are transferred in a partially overlapping manner. This makes it possible to transfer fine patterns with high accuracy to a plurality of adjacent areas on a photosensitive film provided on the main surface of the workpiece and thereby form electronic devices such as semiconductor integrated circuit devices.
The resist shade area of the first aspect of the invention is formed outside the areas in which circuit patterns having halftone characteristics are disposed, whereby overlapping exposure of those areas during the plurality of exposure shots can effectively be prevented.
In addition, although the halftone phase-shift pattern may be constructed by providing projections and depressions on a transparent plate surface, in order to form a finer pattern with higher accuracy and better reproducibility, it is more desirable to deposit a halftone film on the surface of the transparent plate and pattern the film. A halftone phase-shift pattern constructed with a halftone film can offer improved mutual alignment accuracy of the halftone phase-shift mask and work piece, or wafer, if alignment marks are provided for reference on the halftone film.
In accordance with a second aspect of the invention, an electronic device such as a semiconductor integrated circuit device is fabricated as follows: in forming fine holes with dimensions that are not expanded too much two-dimensionally (that is, in the x and y directions) in a dielectric film on the main surface of the wafer to attach electrode terminals extending to the semiconductor area in the wafer, or to form interconnections between wiring layers, a first fine pattern transferring process is performed, which transfers a fine hole pattern to a plurality of adjacent areas on a first photosensitive film provided on the main surface of the wafer by repeatedly stepping or scanning an exposure using a first halftone phase-shift mask with a shade area made of chromium or another metal surrounding a halftone phase-shift pattern corresponding to the fine hole pattern, or a so-called binary mask with a pattern corresponding to the fine hole pattern that is formed by a shade film; in forming narrow or rectangular fine patterns disposed in close proximity to each other, such as gate electrode patterns and wiring patterns, (that is, a plurality of patterns at least having larger longitudinal dimensions than the hole pattern mentioned above, in other words, a plurality of patterns that extend farther in the x or y direction than the hole pattern mentioned above), a second fine pattern transferring process is performed, which transfers a fine wiring pattern to a plurality of adjacent areas on a second photosensitive film provided on the main surface of the wafer by repeating oblique illumination exposure shots a plurality of times with a stepper or a scanner using a second halftone phase-shift mask with a shade area made of resist external to the halftone phase-shift pattern formation area corresponding to the fine pattern.
Furthermore, in the second aspect of the invention, the alignment accuracy of the first mask for forming the fine hole pattern and the second mask for forming the slim electrode and the wiring pattern with respect to the workpiece such as a wafer can be improved by forming the alignment marks of the first mask in the chromium or other metal shade film and the alignment marks of the second mask in the halftone film surrounded by the resist shade area. That is, a fine circuit pattern can be formed with higher dimensional accuracy and higher alignment accuracy thorough lithography by using either a halftone phase-shift mask with a shade area made of resist or a metal shade area mask with alignment wafer marks formed by metal, or both, according to the type of fine patterns to be formed; that is, gate electrodes, wiring, or holes.
Furthermore, in accordance with a third aspect of the invention, the mask used in the first aspect of the invention described above can be made to have no resist material in the fine pattern formation area, so it is possible to form a resist band-like shade area with resist material that fluoresces in response to incident light and easily inspect resist residue defects in the fine pattern part by irradiating the area with inspection light, thereby improving production yields of electronic devices.
In addition, in accordance with another aspect of the invention, it is possible to effectively prevent contamination of fine pattern masks and electronic devices by performing exposure processing by using a mask with a resist shade film formed outside the fine pattern formation area and using the outer region of a mask plate having no resist film to be mounted on the supporter of an aligner and transportation means for transporting the mask, thereby keeping the resist material from coming in contact therewith.
When adopted in the fine patterning processes for gate electrodes, holes, and wiring, the various manufacturing methods of the present invention described above can improve reproducibility and yields in the manufacture of electronic devices such as high-density semiconductor integrated circuit devices.
In order to make the manufacturing process of photomasks easier and more accurate, for example, JP-A No. H5-289307 has disclosed a method of forming a mask pattern with a resist film. This mask is a so-called binary mask comprising exposure light transmitting parts and shade parts with sufficiently low transmittance, which inherently has no problem of overlapping exposure shots.
An example of the use of resist shade areas in a halftone phase-shift mask is found in JP-A No. H9-211837, which prevents sub-peak transfer when circuit patterns are formed, and forms a so-called rim-type halftone mask in which only areas close to the pattern edge are half-toned.
This invention differs in its objects and effects from these methods and also differs in the locations at which resist films are formed.
This invention enables fine patterns to be formed with higher dimensional accuracy and alignment accuracy, making it possible to manufacture electronic devices, such as higher-speed and highly integrated semiconductor integrated circuit devices, with better reproducibility.
First Embodiment
Methods of manufacturing an electronic device such as a semiconductor integrated circuit device according to the present invention will now be described in detail.
An exposure process for transferring a fine pattern will be described with reference to the schematic sectional view of part of an aligner shown in
As shown in
As shown in the drawing, a predetermined area in the photosensitive film (resist film) 115 deposited on the main surface of the wafer 114, such as a chip area of a single semiconductor integrated circuit, is exposed with ArF excimer laser light obliquely incident from the back of the optically transmissive plate 100, the back side being the side without the fine circuit pattern 103.
Next, the exposure process (one exposure shot) is repeated consecutively a plurality of times by stepping or scanning the mask or the wafer in the x and y directions in such a way that the resist shade area is transferred in a partially overlapping manner, until the exposure process has covered the entire photosensitive film (resist film) 115 on the main surface of a large wafer as shown in FIG. 9.
With a high-resolution aligner with high accuracy, it is effective if, instead of exposing the whole surface of a wafer at one time, immediately after the completion of the exposure of a small exposure area (e.g. one corresponding to an area occupied by a single chip) under preset exposure conditions as mentioned above, an area just adjacent to that area is exposed under the same conditions, and this process is repeated in the x and y directions a plurality of times (that is, the exposure is divided into a plurality of shots and repeated).
Because the chip size depends on the product to be made, the resist shade area 102, which forms the outer frame of the mask pattern, is used to obtain a desired shot size (to define the exposure area for one shot) and prevent overlapping exposure of the fine pattern formation area surrounded by the resist shade area during the plurality of exposure shots.
Next, a photo-development process is carried out on the photosensitive film (resist film) 115 on the main surface of the wafer 114 that was exposed as described above to form a pattern corresponding to the fine circuit pattern 103 in a dielectric film or metal film (for simplicity, this film, which is the film being processed, is not shown in the drawing) on the main surface of the wafer.
After that, the photosensitive film (resist film) 115 that was photo-developed is used as an etching mask to selectively etch the dielectric film or metal film thereunder, forming a dielectric film or metal film with a fine pattern corresponding to the fine pattern 103 on the main surface of the wafer 114.
Techniques used in conventional methods of manufacturing semiconductor integrated circuit devices are then employed to create a plurality of electronic devices having fine patterns forming electrodes and wiring in adjacent positions on a single wafer as shown in
Next, a concrete example of a mask used in this method of manufacturing semiconductor integrated circuit devices will be shown in FIG. 2A and
Reference numeral 106 indicates a fine circuit pattern formation area that is made of the halftone film 101; the circuit pattern formation area (that is, the transferred area) 106 is surrounded by the shade area 102, which forms an outer band (or frame) of resist film. In FIG. 2A and
The resist film 102, in which a fine pattern is formed by photo-development, comprises an organic material, allowing the film and pattern to be formed without damaging the halftone film 101. As a result, controllability of phase and transmittance and accuracy of circuit pattern formation on the mask can be improved.
As shown in
A process for manufacturing the halftone phase-shift mask shown in
Here, an SiNxOy film is used as the halftone film material. A ZrSiOx, film, a CrFxfilm, a CrFOx film, an MoSix film, or a double-layer film of ZrSiOx and ZrSiOy can also be used here, where, X and Y indicate composition ratios.
Next, as shown in
As shown in
It is preferable that the film thickness of the resist film 49 may be chosen to yield transmittance with respect to the exposure light of 0.3% or less, together with the halftone film 45 thereunder.
In consideration of repetitive exposure of the corner parts of the rectangular frame-like resist shade area 102 by step-and-repeat in the x and y directions at the time of exposure of the photosensitive film on the semiconductor wafer, if the number of overlapping exposures of the same place is four or less, the film thickness of the resist shade area 102 (or 49), together with the halftone film 45 thereunder, preferably yields a transmittance with respect to the exposure light of 1% or less.
After the mask has been formed in this way, a transparent thin-film pellicle is placed on its main surface to prevent particles from attaching to the pattern formation area thereof. An example will be described with reference to
The mask shown in
In
The structure described above produces the following effects.
(1) Providing a mask with a pellicle makes it possible to prevent the deposition of particles on the mask and avoid the consequent deterioration of the transferred pattern.
(2) Bonding the pellicle mount frame in direct contact with the shade pattern or the mask plate makes it possible to prevent peeling or abrasion of the shade pattern resist film when the pellicle is attached or detached. Therefore, the generation of particles caused by peeling and abrasion of the resist film can be prevented.
As shown in
Next, a diagrammatic sketch of a reduction projection aligner will be shown in FIG. 8. Exposure light emitted from alight source 1501 in the reduction projection aligner is directed through a fly-eye lens 1502, a beam shape adjustment aperture 1503, condenser lenses 1504 and 1505, and a mirror 1506 onto a mask 1507. A masking blade 1522 is placed on the mask, by which the size of the aperture can be adjusted depending on the size of exposure area. The mask 1507 is mounted with its main surface (the first surface), on which the shade (halftone) pattern has been formed, facing down (facing a semiconductor wafer 1509). Therefore, the exposure light is incident on the back surface (the second main surface) of the mask 1507. The mask pattern formed on the mask 1507 is projected through a projection lens 1508 onto the plate to be exposed, i.e., the semiconductor wafer 1509. A pellicle 1510 is provided on the first main surface of the mask 1507 to prevent pattern transfer defects due to the deposition of foreign particles. The mask 1507 is held by suction on a mask stage 1512 controlled by a mask position control means 1511, and the position is measured by detecting reticle alignment marks on the mask 1507 with a position detection means 1513, whereby alignment of the center and the optic axis of the projection lens 1508 is performed accurately. The semiconductor wafer 1509 is held by suction on a specimen table 1514. The specimen table 1514 is mounted on a Z stage 1515 that can be shifted in the optic axis direction of the projection lens 1508, or in the z axis direction, and is also mounted on an X-Y stage 1516. The Z stage 1515 and the X-Y stage 1516 are driven by respective driving means 1518 and 1519 in response to control commands from a servo system 1517, so they can be moved to desired exposure positions. The position is accurately monitored as the position of a mirror 1520 with a laser distance meter 1521. A wafer alignment mark 1523 that has been formed on the wafer is detected by a wafer mark detection system 1524, and the position information is sent to the servo system 1517 for alignment.
As described above, the resist film forming the shade area is removed completely for the area on the mask that may come into contact with the aligners or transportation means, to prevent generation of particles when the mask is mounted on the aligner and transported. When this removal process was omitted, particles were generated, causing transfer defects.
Next, in order to make the characteristics of the masks shown in
In a mask for forming a fine hole pattern with dimensions that are not expanded two-dimensionally (that is, in the x and y directions), the wafer alignment marks, indicated with reference numeral 205 in
Furthermore, in order to make it easier to understand the method shown in
First, as shown in
The mask forming method shown in
This limitation of the range of alternatives becomes a significant problem in a mask for an ArF excimer laser (having a wavelength of 193 nanometers) or an F2 excimer laser (having a wavelength of 157 nanometers) that emits highly energetic exposure light and makes exposure light irradiation resistance a particularly important issue, so a halftone mask using the resist shade area shown in
Second Embodiment
A method of manufacturing a semiconductor integrated circuit device having a twin-well complementary MIS (CMIS) circuit using the present invention will now be described with reference to
On the main surface (the first surface), a field dielectric film 7 for isolation, made of a silicon oxide film or the like, is formed by local oxidization of silicon (LOCOS) or another method. This isolation area can be of the trench type. That is, the isolation area can also be formed by filling a dielectric film into a groove that has been excavated into the thickness of the semiconductor substrate 3s.
An n-type MISFET Qn and a p-type MISFET Qp are formed in respective semiconductor active regions surrounded by the field dielectric film 7. The gate dielectric film 8 of the n-type MISFET and p-type MISFET is an oxide film formed by, for example, thermal oxidation of silicon.
The narrow gate electrode 9 of each of these n-type and p-type MISFETs is formed as follows: a gate formation film made of low-resistance polysilicon is deposited by a chemical vapor deposition (CVD) method; then a photosensitive film (resist film) is deposited onto the whole surface of the film; the photosensitive film is exposed by using the ArF excimer laser reduction projection aligner shown in
The oblique illumination system is effective not only in the controllability of gate pattern dimensions but also in the accuracy of the shapes and positions of reference alignment marks that are formed at the same time as the gate pattern. It has become clear that an alignment mark having a wider line width than that of the gate pattern is affected by lens aberration, and the accuracy of its shape and position is reduced, when a halftone film is used. This problem is solved by using an oblique illumination system; thus the alignment accuracy of a contact hole layer that is aligned with the gate layer, for example, is improved.
A semiconductor region 10 that constitutes the source and drain of the n-type MISFET Qn in
Next, after an inter-layer dielectric film 12 such as a silicon oxide film, for example, is deposited on the semiconductor substrate 3s by CVD or another method, a polysilicon film 13 is deposited on the upper surface by CVD or another method. Then the polysilicon film 13 is patterned by photolithography technology, using the KrF excimer laser reduction projection aligner shown in
After that, as shown in
The reason why this hole patterning process uses the mask shown in
In the exposure of a fine hole pattern, the exposure light diffracts and expands in both the x and y directions, reducing the effective pattern exposure strength of the projected image. A method of forming a pattern of holes of a predetermined size on a wafer by exposing the pattern with an increased amount of exposure light has therefore been suggested. However, when a wafer alignment mark with dimensions larger than the hole pattern and with less of a two-dimensional diffraction effect is exposed with this relatively large amount of exposure light, the mark is overexposed. For example, the typical size of a hole pattern is 1.0 μm to 1.5 μm (micrometer) on the mask but the line width of an alignment mark is 15 μm, so if a mask with a wafer alignment mark surrounded by a halftone film as shown in
On the other hand, in the case of the mask shown in
Although this embodiment uses a halftone mask having a Cr shade area as shown in
For effective performance of the fine pattern exposure and alignment operations in various processes, it is preferable if the expensive aligner can be used in common for these processes, without large alterations of the exposure conditions depending on the process. For this reason, the halftone mask shown in
As described above, in the mask shown in
We return now to the description of the CMIS fabrication process. After a metal film made of tungsten or other metal is deposited on the semiconductor substrate 3s that has been obtained in
After this, second and subsequent layers of wiring (not shown in the drawing) are formed in the same way, above the first layer of wiring to fabricate the semiconductor integrated circuit device.
CMIS devices fabricated according to this method showed a 4% improvement in dimensional accuracy in lithography transfer and caused no faulty alignment. Therefore, yields in the production of high-speed LSI chips increased by 5%.
As can be understood from this embodiment, it is preferable that the manufacture of semiconductor integrated circuit devices uses a first halftone phase-shift mask with a metal shade film, or the binary mask, for forming fine- dimensioned hole patterns having little two-dimensional expansions, and a second halftone phase-shift mask with a resist shade area as shown in
Third Embodiment
Next, as a third embodiment, a method of manufacturing a semiconductor memory device will be described with reference to
As shown in
Next, as shown in
Next, a storage electrode (capacitor electrode) 78 is formed, on which a film of Ta2O5 , Si3N4, SiO2, BST, PZT, or a ferroelectric substance, or a compound film there of, is deposited to form a capacitor dielectric film 79. Further, poly-crystalline Si, a high melting point metal, a high melting point metal silicide, or a low-resistance conductor such as Al or Cu is deposited to form a plate electrode 80 (FIG. 10C).
Next, as shown in
A pattern formed through lithography according to the present invention will be described below.
The word lines 82 and 87 and the data lines 83 and 88 are formed by using a halftone phase-shift mask having a resist shade film as shown in
If the pattern density, that is the ratio of light transmitted areas to the mask exposed area, exceeds about 25%, the optimum amount of exposure light of the circuit pattern is around a level that does not affect the geometrical symmetry of the transferred wafer alignment marks. A halftone phase-shift mask with a resist shade area has higher phase controllability and dimensional accuracy, as described above, thus a higher lithographic transfer accuracy. In addition, as shown in
On the other hand, formation of the electrode contact hole patterns 86 and 91 uses a halftone phase-shift mask with a Cr shade area as shown in
Semiconductor memory devices manufactured by using the present invention have shown the following specific improvements in their characteristics: (1) faster and more stable read operation, due to reduced line width variation in word lines; and (2) more stable data retention characteristics, due to reduced variation in storage electrode area.
Although these descriptions have focused on the use of the present invention to manufacture a dynamic random access memory (DRAM) chip, the invention is not limited to this application; it can also be used to manufacture a semiconductor integrated circuit device having another type of memory circuit such as a static random access memory (SRAM) or a flash memory (or electrically erasable read-only memory (EEPROM)), a semiconductor integrated circuit device having a logic circuit such as a microprocessor, or a mixed type semiconductor integrated circuit device having both memory and logic circuits integrated on the same semiconductor substrate.
Although the examples in the various embodiments have mainly been of halftone phase-shift patterns formed in a halftone film with alignment marks provided in the halftone film to obtain better alignment accuracy, as shown in
Although the embodiments above have mainly described a method of manufacturing a semiconductor integrated circuit device by transferring various fine patterns onto a semiconductor wafer, the present invention is not limited to this application; it can also be applied to the manufacture of other electronic devices having extremely fine patterns, such as superconductive devices, and to the manufacture of micro machines.
In the invention, fine patterns can be formed with high dimensional accuracy and high alignment accuracy. Therefore, an electronic device of such as a semiconductor integrated circuit device having high operation speed or high integration density is manufactured with high reproducibility.
Hasegawa, Norio, Tanaka, Toshihiko
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